Label | Explanation | Data Type |
Input Features | A list of the input feature classes or layers. When the distance between features is less than the cluster tolerance, the features with the lower rank will snap to the feature with the higher rank. The highest rank is 1. | Value Table |
Output Feature Class | The output feature class. | Feature Class |
Attributes To Join (Optional) | Specifies which attributes from the input features will be transferred to the output feature class.
| String |
XY Tolerance (Optional) | The minimum distance separating all feature coordinates (nodes and vertices) as well as the distance a coordinate can move in x or y (or both). Caution:Changing this parameter's value may cause failure or unexpected results. It is recommended that you do not modify this parameter. It has been removed from view on the tool dialog box. By default, the input feature class's spatial reference x,y tolerance property is used. | Linear Unit |
Output Type (Optional) | Specifies the type of intersections to be returned.
| String |
Summary
Computes a geometric intersection of the input features. Features or portions of features that overlap in all layers or feature classes will be written to the output feature class.
An alternate tool is available for intersect operations. See the Pairwise Intersect tool documentation for details.
The Pairwise Intersect tool is similar to the Intersect tool in that geometric intersections are computed, but it is different in that intersections are computed on pairs of features rather than all combinations of features.
Illustration
Usage
The Input Features parameter value must be simple features: point, multipoint, line, or polygon. They cannot be complex features such as annotation features, dimension features, or network features.
If the inputs have different geometry types (that is, line on poly, point on line, and so on), the Output Feature Class geometry type will default to be the same as the Input Features geometry type with the lowest dimension geometry. For example, if one or more of the inputs is of type point, the default output will be point; if one or more of the inputs is line, the default output will be line; and if all inputs are polygon, the default output will be polygon.
The Output Type parameter value can be that of the Input Features parameter with the lowest dimension geometry or lower. For example, if all the inputs are polygons, the output can be polygon, line, or point. If one of the inputs is of type line and none are points, the output can be line or point. If any of the inputs are point, the Output Type value can only be point.
Attribute values from the input feature classes will be copied to the output feature class. However, if the input is a layer or layers created by the Make Feature Layer tool and a field's Use Ratio Policy is checked, then a ratio of the input attribute value is calculated for the output attribute value. When Use Ratio Policy is enabled, whenever a feature in an overlay operation is split, the attributes of the resulting features are a ratio of the attribute value of the input feature. The output value is based on the ratio in which the input feature geometry was divided. For example, if the input geometry was divided equally, each new feature's attribute value is assigned one-half of the value of the input feature's attribute value. Use Ratio Policy only applies to numeric field types.
Caution:
Geoprocessing tools do not honor geodatabase feature class or table field split policies.
This tool will use a tiling process to handle very large datasets for better performance and scalability. For more details, see Geoprocessing with large datasets.
This tool honors the Parallel Processing Factor environment. If the environment is not set (the default) or is set to 0, parallel processing will be disabled. Setting the environment to 100 will enable parallel processing. Up to 10 cores will be used when parallel processing is enabled.
Parallel processing is currently supported for polygon-on-polygon, line-on-polygon, and point-on-polygon overlay operations.
License:
With ArcGIS Desktop Basic and Desktop Standard licenses, the number of input feature classes or layers is limited to two.
Parameters
arcpy.analysis.Intersect(in_features, out_feature_class, {join_attributes}, {cluster_tolerance}, {output_type})
Name | Explanation | Data Type |
in_features [[in_features, {Rank}],...] | A list of the input feature classes or layers. When the distance between features is less than the cluster tolerance, the features with the lower rank will snap to the feature with the higher rank. The highest rank is 1. For more information, see Priority ranks and geoprocessing tools. | Value Table |
out_feature_class | The output feature class. | Feature Class |
join_attributes (Optional) | Specifies which attributes from the input features will be transferred to the output feature class.
| String |
cluster_tolerance (Optional) | The minimum distance separating all feature coordinates (nodes and vertices) as well as the distance a coordinate can move in x or y (or both). Caution:Changing this parameter's value may cause failure or unexpected results. It is recommended that you do not modify this parameter. It has been removed from view on the tool dialog box. By default, the input feature class's spatial reference x,y tolerance property is used. | Linear Unit |
output_type (Optional) | Specifies the type of intersections to be returned.
| String |
Code sample
The following Python window script demonstrates how to use the Intersect function in immediate mode.
import arcpy
arcpy.env.workspace = "C:/data/RedRiver_basin.gdb"
arcpy.Intersect_analysis(["vegetation_stands", "road_buffer200m", "water_buffer100"], "mysites", "ALL")
arcpy.Intersect_analysis([["vegetation_stands", 2], ["road_buffer200m", 1], ["water_buffer100", 2]],
"mysites_ranked", "ALL")
The following stand-alone script uses the Intersect function as part of a workflow with other analysis tools to determine the type of vegetation within 100 meters of all stream crossings.
#Name: VegRoadIntersect.py
# Purpose: Determine the type of vegetation within 100 meters of all stream
# crossings
# Import system modules
import arcpy
# Set the workspace (to avoid having to type in the full path to the data every
# time)
arcpy.env.workspace = "c:/data/data.gdb"
# Process: Find all stream crossings (points)
inFeatures = ["roads", "streams"]
intersectOutput = "stream_crossings"
arcpy.Intersect_analysis(inFeatures, intersectOutput, "", "", "point")
# Process: Buffer all stream crossings by 100 meters
bufferOutput = "stream_crossings_100m"
bufferDist = "100 meters"
arcpy.Buffer_analysis(intersectOutput, bufferOutput, bufferDist)
# Process: Clip the vegetation feature class to stream_crossing_100m
clipInput = "vegetation"
clipOutput = "veg_within_100m_of_crossings"
arcpy.Clip_analysis(clipInput, bufferOutput, clipOutput)
# Process: Summarize how much (area) of each type of vegetation is found
# within 100 meters of the stream crossings
statsOutput = "veg_within_100m_of_crossings_stats"
statsFields = [["shape_area", "sum"]]
caseField = "veg_type"
arcpy.Statistics_analysis(clipOutput, statsOutput, statsFields, caseField)
Environments
Licensing information
- Basic: Limited
- Standard: Limited
- Advanced: Yes